Smart small-bore connector device

ABSTRACT

A connector device includes a connector. An electrical lead wire is positioned in the connector. The electrical lead wire is configured to provide communication between the connector device and an external device. In certain embodiments, the electrical lead wire includes a contact point on a surface of the connector for electrically coupling the connector device to the external device. In addition to or as an alternative to the electrical lead wire, the connector device may include an optical coupling or channel in the connector configured for optical light transmission between the connector device and the external device.

RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No.16/108,974, filed Aug. 22, 2018, and entitled SMART SMALL-BORE CONNECTORDEVICE, which claims the benefit of U.S. Provisional Application No.62/554,905, filed Sep. 6, 2017, and entitled SMART SMALL-BORE CONNECTORDEVICE, which are hereby incorporated by reference in their entirety.

TECHNICAL FIELD

The present disclosure is directed to small-bore connector devices forliquids and gases. More specifically, the present disclosure is directedto smart small-bore devices for healthcare applications having a fittingor connection that includes one or more electrical lead wires and one ormore corresponding electrical contacts to electrically couple the smartsmall-bore connector device with an external device, such as a deliverydevice and/or a monitoring device.

BACKGROUND

Luer fittings or connections are used extensively in medical and lifesciences applications. Conventional Luer fittings are typicallysmall-bore, leak-proof couplings used to couple tubing and equipment forthe transfer of fluids and gases, for example.

Conventional Luer fittings include slip Luer fittings and Luer lockfittings. The specifications and performance of these fittings arecovered by International Standard ISO 80369 entitled “Small-boreconnectors for liquids and gases in healthcare applications.” The slipLuer fittings simply conform to Luer taper dimensions and are pressedtogether and held by friction, and the Luer lock fittings include atwist-lock mechanism to hold a hypodermic needle safely in place, forexample. The Luer lock fitting allows the needle to be coupled andremoved from a syringe, minimizing a risk that the needle slips off thesyringe and/or that the syringe tip breaks. The cooperating slip Luerfittings slip together to form a seal. Cooperating Luer lock fittings,on the other hand, have interlocking threads to maintain the leak-proofcoupling between the needle and the syringe. One portion of the Luerlock fitting (e.g., the syringe tip) has a housing with externalthreads, while the cooperating portion of the Luer lock fitting (e.g.,the base of the needle) has a housing with internal threads. Thesethreads urge the two portions together to provide a leak-proof couplingthat can be easily disengaged.

Luer fittings or connections are widely used in laboratories, medicaldevices and intervention therapies. Examples of Luer fittings include,without limitation, intravenous catheters, feeding tubes, ventilators,and the common hypodermic syringe. Luer fittings are available in avariety of materials, such as nylon, polycarbonate, polypropylene,polyether ether ketone (PEEK), and stainless steel, for example.

BRIEF SUMMARY OF SOME EXAMPLE EMBODIMENTS

In one aspect, a small-bore connector device includes a plurality ofconductive elements, such as electrical lead wires, positioned in orinsert molded into at least a portion of the small-bore connectordevice, e.g., at an adapter or base of the small-bore connector device.Each conductive element includes a contact point on a surface of thesmall-bore connector device and coupled to a respective electrical leadwire. For example, the contact point may be positioned on an outersurface of the base or on a surface of a flange at the proximal end ofthe small-bore connector device. The conductive elements may have anysuitable number of contact points. The one or more electrical lead wireselectrically couple, e.g., in signal communication, the small-boreconnector device and, in certain embodiments, a medical device,component, or instrument operatively coupled to the small-bore connectordevice, to an external device, such as a monitoring device and/ordelivery device.

In another aspect, a small-bore connector device includes one or moresuitable optical connections, e.g., one or more optical fibers, formedor molded in the small-bore connector device for optical lighttransmission (fiber optic transmission) between the small-bore connectordevice and an external device, such as a monitoring device and/ordelivery device. In certain embodiments, this feature is molded in aclear material to provide a fiber optic transmission line or cablewithout requiring additional parts or components. Additionally oralternatively, one or more data connections, similar to a TOS-LINK®audio transmission cable, is positioned or molded in the small-boreconnector device for data transmission through the small-bore connectordevice.

In another aspect, a catheter assembly includes a catheter having adistal end and an opposing proximal end. A connector is coupled in fluidcommunication to the proximal end of the catheter. The connectorincludes a base including a sensor assembly having at least one sensor.The at least one sensor is configured to sense one or more environmentalcharacteristics at an access site and generate at least one signalrepresentative of the one or more environmental characteristics. Anelectrical lead wire operatively couples the at least one sensor to anexternal device. The electrical lead wire is configured to transmit theat least one signal received from the at least one sensor to theexternal device.

In another aspect, a catheter assembly includes a catheter having adistal end and an opposing proximal end, and a cannula extending fromdistal end toward proximal end. A connector is coupled in fluidcommunication with the catheter. The connector is configured to provideelectrical communication between the catheter assembly and an externaldevice. The connector includes a base having a flange forming threads. Asensor assembly is coupled to the base. The sensor assembly isconfigured to sense one or more environmental characteristics at anaccess site and generate at least one signal representative of the oneor more environmental characteristics. A coupling is configured tooperatively couple the connector to the external device. The coupling isconfigured to transmit at least one of a data signal and a commandsignal between the sensor assembly and the external device.

In another aspect, a connector device includes a connector configured toprovide electrical communication between the connector device and anexternal device. The connector includes a base having a flange formingthreads. A sensor is coupled to the base. The sensor is configured tosense an environmental characteristic at an access site and generate asignal representative of the environmental characteristic. A coupling isconfigured to operatively couple the connector to the external device.The coupling is configured to transmit a signal between the sensor andthe external device.

BRIEF DESCRIPTION OF THE DRAWINGS

FIGS. 1-3 are perspective side views of example small-bore connectordevices with alternative contact points, contact positions, and/orcontact locations;

FIGS. 4 and 5 are perspective side views of example small-bore connectordevices including insert molded electrical connection elements thatterminate on a surface of the small-bore connector device; and

FIG. 6 is a partial perspective side view of an example small-boreconnector device including an optical (fiber optic) transmission lineinsert molded into the small-bore connector device.

DETAILED DESCRIPTION

Various embodiments are described below with reference to the drawingsin which like elements generally are referred to by like numerals. Therelationship and functioning of the various elements of the embodimentsmay better be understood by reference to the following detaileddescription. However, embodiments are not limited to those illustratedin the drawings. It should be understood that the drawings are notnecessarily to scale, and in certain instances details may have beenomitted that are not necessary for an understanding of embodimentsdisclosed herein, such as—for example—conventional fabrication andassembly.

The invention is defined by the claims, may be embodied in manydifferent forms, and should not be construed as limited to theembodiments set forth herein; rather, these embodiments are provided sothat this disclosure will be thorough and complete, and will fullyconvey enabling disclosure to those skilled in the art. As used in thisspecification and the claims, the singular forms “a,” “an,” and “the”include plural referents unless the context clearly dictates otherwise.Reference herein to any industry standards (e.g., ASTM, ANSI, IEEE, ISOstandards) is defined as complying with the currently publishedstandards as of the original filing date of this disclosure concerningthe units, measurements, and testing criteria communicated by thosestandards unless expressly otherwise defined herein. The terms“proximal” and “distal” are used herein in the common usage sense wherethey refer respectively to a handle/doctor-end of a device or relatedobject and a tool/patient-end of a device or related object. The terms“about,” “substantially,” “generally,” and other terms of degree, whenused with reference to any volume, dimension, proportion, or otherquantitative or qualitative value, are intended to communicate adefinite and identifiable value within the standard parameters thatwould be understood by one of skill in the art (equivalent to a medicaldevice engineer with experience in this field), and should beinterpreted to include at least any legal equivalents, minor butfunctionally-insignificant variants, standard manufacturing tolerances,and including at least mathematically significant figures (although notrequired to be as broad as the largest range thereof).

In example embodiments, previously unused space on a small-bore fittingor connection, such as a small-bore connector device, is utilized tofacilitate electrical communication, e.g., power and/or signalcommunication, between a suitable upstream source, such as a therapyinfusate source, and the small-bore fitting or connection used for anysuitable type of patient access. The example small-bore connector deviceis suitable for use in infusion therapy, for Peripherally InsertedCentral Catheter (PICC) lines, shunts, and ports, for example. Thesmall-bore fitting or connection can be used on needleless connectors orany device that utilizes a small-bore compatible fitting or connectionfor fluid flow or fluid communication. The example small-bore connectordevices provide a communication device that can link in a closed loopthe inserted medical device with any type of delivery or informationsystem via an electrical and data connection built into the small-boreconnector device. In example embodiments, the small-bore fittings orconnections include communication devices in the defined space of thesmall-bore fitting or connection to provide power and/or datatransmission into and/or out of the connection through the small-borefitting or connection, and feedback from the distal side back to theproximal side. The example small-bore connectors described hereinsatisfy the requirements of International Standards ISO 80369 forpassage of liquids and gases in healthcare applications and provideimprovements or enhancements to add advanced functionality to thestandard small-bore connectors satisfying the requirements of ISO 80369.In alternative embodiments, the example small-bore connector device maybe suitable for other applications not associated with ISO 80369.

A smart small-bore connector device, as described herein, provideselectrical communication, e.g., power and/or signal communication,between a medical device or instrument at a distal end of the smartsmall-bore connector device and an external device, such as a fluid ormedication delivery device and/or a monitoring device, at an opposingproximal end of the smart small-bore connector device. The medicaldevice or instrument may include a sensor assembly that providesvaluable sensing data with access to a patient's vein, artery, or otherbiological access, for example. Such data may be representative of oneor more environmental characteristics at the access site including,without limitation, a temperature within a body lumen, a blood pressurewithin the body lumen, a blood glucose level, a sodium level, apotassium level, an indication of pregnancy, a drug concentration level,a white blood cell count, different markers, proteins, and/or chemicalsin the patient's blood stream, or any combination thereof.

As described herein, a sensor assembly at the distal end of the smartsmall-bore connector device includes a sensor or an array of sensorspositioned within a vein or an artery to directly contact the patient'sblood stream. Each sensor is operatively coupled to the external deviceusing one or more electrical lead wires that are molded in the smartsmall-bore connector device or coupled to an outside surface or aninside surface of the smart small-bore connector device, for example. Inexample embodiments, the external device at the proximal end of thesmart small-bore connector device is configured with one or more of avariety of electronic and/or communication components to provide power,data transmission, data collection, and/or data analysis capabilities,as well as other capabilities.

In example embodiments, the sensor assembly is configured to sense oneor more environmental characteristics within or related to a patient'sbiological functions including blood or blood stream and generate andtransmit one or more signals representative of the one or moreenvironmental characteristics to the external device via the one or moreelectrical lead wires of the smart small-bore connector device. Forexample, in example embodiments, the sensor assembly includes one ormore sensors, e.g., one sensor or a plurality of sensors. Each sensor ofthe sensor assembly is configured to measure one or more environmentalcharacteristics, such as described above. Further, the sensor assemblymay include one or more particular sensors including, withoutlimitation, a temperature sensor, a sensor that senses a chemical withina patient's blood, a sensor that senses a marker in the patient's blood,a sensor that senses a protein in the patient's blood, or anycombination thereof.

In alternative example embodiments, a wire configuration including oneor more electrical lead wires may be operatively coupled to the externaldevice to provide suitable communication protocols, e.g., USB levelcommunication having four electrical lead wires, which can enable a widerange of sensors, data rates and/or data types on a well-defined BUS.Other suitable communication protocols include, for example, simpleplugin, Wi-Fi, Bluetooth® wireless technology, a universal serial busconnector, Radio Frequency Identification (RFID), Near FieldCommunication (NCF, a derivative of RFID), and self-contained displays.

Referring now to the figures, and initially to FIGS. 1-3, an examplecatheter 10 has a distal end 12 and an opposing proximal end 14.Catheter 10 may include a cannula 16 extending from distal end 12 towardopposing proximal end 14 of catheter 10 in certain example embodiments.Catheter 10 forms or defines a lumen 18 extending between distal end 12and proximal end 14 of catheter 10. In example embodiments, catheter 10is configured to couple to a cooperating small-bore fitting orconnection, tubing, a hub, or another suitable connection (not shown inFIGS. 1-6) such that lumen 18 provides a fluid flow path throughcatheter 10. In example embodiments, lumen 18 has a suitable diameter ora suitable cross-sectional dimension to facilitate fluid flow throughcatheter 10. Additionally or alternatively, lumen 18 may accommodate amedical device or instrument, such as an obturator, for example, that ismovably positioned within lumen 18.

At proximal end 14, catheter 10 includes an adapter, such as asmall-bore connector 20 shown in FIGS. 1-3, for example. Small-boreconnector 20 is configured to removably couple to any suitable medicaldevice or component, for example, a cooperating small-bore fitting, adevice, or a medical tubing. The medical device, component, or tubingmay include a cooperating element, such as a cooperating small-boreconnector, to facilitate coupling the medical device, component, ortubing, for example, to catheter 10. In the example embodiments shown inFIGS. 1-6, small-bore connector 20 is a small-bore connection. In theseembodiments, small-bore connector 20 includes a twist-lock mechanism 22to removably couple small-bore connector 20 to a cooperating small-boreconnector having a cooperating twist-lock mechanism. For example, a base24 of small-bore connector 20 may have one or more external threads 26formed on a flange 28 of small-bore connector 20 that interlocks with acooperating internal thread of the cooperating small-bore connector todraw or urge small-bore connector 20 towards the cooperating small-boreconnector to maintain a substantially leak-proof coupling betweensmall-bore connector 20 and the cooperating small-bore connector.Small-bore connector 20 can be easily disengaged from the cooperatingsmall-bore connector by rotating small-bore connector 20 in an oppositedirection with respect to the cooperating Luer connector to disengagethe threads. In alternative example embodiments, small-bore connector 20may be a slip small-bore fitting that is pressed onto the cooperatingsmall-bore connector.

In example embodiments, small-bore connector 20 includes one or morecouplings including, without limitation, one or more electricalcouplings, one or more optical couplings, and/one or more resistivecouplings. In certain example embodiments, the one or more electricalcouplings electrically couple, e.g., in signal communication, electricand/or electronic components on and/or within catheter 10 and/oroperatively coupled to catheter 10 to an external device positioned atproximal end 14 of catheter 10 or remotely from catheter 10. Theexternal device may include a delivery device and/or a monitoringdevice, for example, having one or more microcontrollers or processors.The one or more electrical couplings may provide power from a powersource, e.g., a battery, to the electric and/or electronic components ofcatheter 10. For example, the one or more electrical couplings mayelectrically couple one or more sensors at distal end 12 of catheter 10or small-bore connector 20 to the external device at proximal end 14 totransmit data signals and/or command signals between the sensors and theexternal device.

Referring further to FIGS. 1-6, catheter 10 includes one or moreelectrical lead wires, e.g., a plurality of electrical lead wires 30,namely, electrical lead wires 30 _(a), 30 _(b), . . . , 30 _(n), 30_(n+1). Electrical lead wires 30 electrically couple, e.g., in signalcommunication, electrical components associated with catheter 10 to anexternal device or component at proximal end 14 of catheter 10, forexample. The electrical components may include one or more sensors, anelectronic module, circuitry, a microcontroller, and/or a circuit boardon catheter 10 or operatively coupled to catheter 10, for example. Inexample embodiments, one or more sensors are coupled in signalcommunication to an external device, such as a delivery device and/or amonitoring device, through electrical lead wires 30 to provide sensingcapabilities.

In certain example embodiments, at least a portion of each electricallead wire 30 is molded onto or molded in catheter 10, for example,molded on or within small-bore connector 20. Each electrical lead wire30 may extend along a surface of a wall of catheter 10 or may beembedded or molded within at least a portion of a length of the catheterwall between distal end 12 and proximal end 14. As shown in FIGS. 4 and5, in example embodiments, catheter 10 includes a plurality ofelectrical lead wires 30 _(a), 30 _(b), . . . , 30 _(n), 30 _(n+1)forming a first array 32 of electrical lead wires 30 arranged in aparallel configuration. Each electrical lead wire 30 is embedded withinsmall-bore connector 20 and terminates at a contact 34 on a proximalsurface 36 of flange 28. In certain example embodiments, catheter 10also includes an additional plurality of electrical lead wires 30 _(a),30 _(b), . . . , 30 _(n), 30 _(n+1) forming a redundant or second array40 of electrical lead wires 30 arranged in a parallel configuration andembedded within small-bore connector 20. Each electrical lead wire 30 ofsecond array 40 terminates at a contact point 42 on proximal surface 36of flange 28. As shown in FIG. 5, in certain example embodiments,catheter 10 may alternatively or in addition to first array 32 and/orsecond array 40 include a third array 44 of electrical lead wires 30_(a), 30 _(b), . . . , 30 _(n), 30 _(n+1) arranged in a parallelconfiguration. Each electrical lead wire 30 of third array 44 isembedded within small-bore connector 20 and terminates at a contactpoint 46 on proximal surface 36 of flange 28.

Referring again to FIGS. 1-3, contact points 34, 42, and/or 46 can bepositioned at any suitable location on catheter 10. For example, asshown in FIG. 1, contact points 34 and/or contact points 42 may beformed through a cylindrical wall 48 of small-bore connector 20, moldedinto cylindrical wall 48, or formed on an outer surface of cylindricalwall 48. Any suitable number of contact points 34, 42 with correspondingelectrical lead wires 30 may be present on or within small-boreconnector 20. Contact points 34, 42 may be used to provide power to anelectric or electronic component associated with catheter 10 and/or adevice operatively coupled to catheter 10, as well as facilitate thetransmission of signals between catheter 10 and an external deviceoperatively coupled to catheter 10. Contact points 34, 42 may also beused as a standard USB connection to operatively couple small-boreconnector 20 to an external device or a cooperating small-bore connectorfor another suitable device in certain embodiments. Additionally oralternatively, as described above, one or more contact points, such ascontact points 46, may be molded into or formed on a surface of flange28, e.g., proximal surface 36, or on a surface of one or more externalthreads 26.

As shown in FIG. 2, one or more contact points may form a coil orcylindrical rings 56 positioned about an outer surface of cylindricalwall 48 to provide contact or interaction with spring fingers on acooperating small-bore fitting or connection, for example. As shown inFIG. 3, one or more contact points, such as contact points 46, may bemolded into or formed on a distally-facing surface 58 of flange 28providing for a quick connect or snap fit to couple electrical leadwires 30 to the external device.

In an alternative example embodiment as shown in FIG. 6, one or moresuitable optical couplings 60, e.g., one or more optical fibers, can bebuilt in, e.g., molded in, small-bore connector 20 for optical lighttransmission (fiber optic transmission) between small-bore connector 20and an external device 62, such as a monitoring device and/or a deliverydevice. In certain embodiments, this feature is molded in a clearmaterial to provide a fiber optic transmission line or cable withoutrequiring additional parts or components. Additionally or alternatively,one or more data connections 64, similar to a TOS-LINK® style audiotransmission cable, can be built in, e.g., molded in, small-boreconnector 20 for data transmission between the patient therapy side,e.g., small-bore connector 20, and external device 62. Data connections64 can be created with more specialized optical fiber cables as needed.

In example embodiments, the external device, e.g., a monitoring deviceand/or a delivery device, includes one or more processors configured totransmit signals to and receive signals from the sensor assembly. Incertain embodiments, a communication module or circuitry operativelycoupled to small-bore connector 20 is electrically coupled to, e.g., insignal communication with, the external device for wirelesscommunication with the external device or an external processor. Inthese embodiments, the communication module or circuitry includes aradio frequency identification transmitter, a near field communicationtransmitter, a Bluetooth® wireless technology transmitter, a universalserial bus connector, or any suitable combination thereof. The externaldevice may include one or more processors and one or morecomputer-readable media, one or more communication interfaces, and oneor more power sources. The communication interfaces may support bothwired and wireless connection to various networks, such as cellularnetworks, radio, Wi-Fi networks, short range networks (e.g., Bluetooth®technology), and infrared (IR) networks, for example.

Depending on the configuration of the external device, thecomputer-readable media is an example of computer storage media and mayinclude volatile and nonvolatile memory. Thus, the computer-readablemedia may include, without limitation, RAM, ROM, EEPROM, flash memory,and/or other memory technology, and/or any other suitable medium thatmay be used to store computer-readable instructions, programs,applications, media items, and/or data which may be accessed by theexternal device. The computer-readable media may be used to store anynumber of functional components that are executable on a processor. Theexternal device may have additional features or functionality. Forexample, the external device may also include additional data storagedevices (removable and/or non-removable). The additional data storagemedia, which may reside in a control board, may include volatile andnonvolatile, removable and non-removable media implemented in any methodor technology for storage of information, such as computer readableinstructions, data structures, program modules, or other data. Inaddition, some or all of the functionality described as residing withinthe external device may reside remotely from the external device.

Below are several non-limiting, example applications for catheter 10including small-bore connector 20.

In a first example application, a patient therapy site includes a smallblood glucose sensor. An infusing pump is configured to power the sensorthrough two connections on small-bore connector 20, and send and receiveinformation or data via one or more signals from the sensor tounderstand how to properly administer a proper amount of insulin oranother balancing element.

In a second example application, catheter 10 includes a resistiveelement in small-bore connector 20 that identifies a size and/or a gaugefor the therapy site. A pump or another suitable therapy device isconfigured to deliver a correct flow rate or a maximum safe flow rate.The resistive value could also indicate a type of device coupled tocatheter 10 at small-bore connector 20; thus, facilitating theelimination or decrease in procedures and therapies that might not becompatible with the delivery mechanism.

In example embodiments described herein, a smart small-bore connectordevice includes a small-bore connector and one or more electrical leadwires in the small-bore connector. The electrical lead wires areconfigured to provide power to the smart small-bore connector deviceand/or communication between the smart small-bore connector device andan external or remote device. Each electrical lead wire includes acontact point on a surface of the small-bore connector for electricallycoupling the smart small-bore connector device to the external or remotedevice.

In certain embodiments, the smart small-bore connector device includesone or more electrical wires used for power transmission and/or for datatransmission. One or more of the electrical wires may be positioned on aproximal flange of the small-bore connector, on a distal side or surfaceof the small-bore connector threads, ears and/or flange, and/or on theouter diameter a fluid connection and sealing area of the small-boreconnector.

In certain example embodiments, a smart small-bore connector deviceincludes a small-bore connector and at least one optical channel thatprovides a contact or interface point on a surface of the small-boreconnector for optically coupling the smart small-bore connector deviceto an external or remote device. In certain embodiments, the at leastone optical channel may be molded into the mating small-bore connectorwith a dissimilar material from the small-bore connector material. Theoptical channel is molded into the mating small-bore connector with afiber optic cable assembly.

In a third example application, catheter 10 includes an electricalserial number, and, when first used, catheter 10 is configured tocommunicate with the external device to record a date, a time, and apatient's name, for example. An external database is used to track atherapy time and/or a replacement time, for example. This activeidentification can then be used to prompt healthcare workers to takeappropriate action when alerted, e.g., remove or provide maintenance ofcatheter 10 or a medical device or instrument operatively coupled tocatheter 10.

In a fourth example application, small-bore connector 20 is configuredfor optical light transmission. In this example application, small-boreconnector 20 includes an optical fiber molded into small-bore connector20 to facilitate communication between catheter 10 and the externaldevice, e.g., a monitoring device and/or a delivery device.

Those of skill in the art will appreciate that embodiments not expresslyillustrated herein may be practiced within the scope of the claims,including that features described herein for different embodiments maybe combined with each other and/or with currently-known orfuture-developed technologies while remaining within the scope of theclaims. Although specific terms are employed herein, they are used in ageneric and descriptive sense only and not for purposes of limitationunless specifically defined by context, usage, or other explicitdesignation. It is therefore intended that the foregoing detaileddescription be regarded as illustrative rather than limiting. And, itshould be understood that the following claims, including allequivalents, are intended to define the spirit and scope of thisinvention. Furthermore, the advantages described above are notnecessarily the only advantages of the invention, and it is notnecessarily expected that all of the described advantages will beachieved with every embodiment. In the event of any inconsistentdisclosure or definition from the present application conflicting withany document incorporated by reference, the disclosure or definitionherein shall be deemed to prevail.

What is claimed is:
 1. A catheter assembly, comprising: a catheterhaving a distal end and an opposing proximal end, wherein a longitudinalaxis extends between the distal end and the proximal end, wherein thecatheter comprises a cannula disposed at the distal end; and a connectorcoupled in fluid communication to the proximal end of the catheter, theconnector comprising: a base extending along the longitudinal axis andcomprising a flange extending in a perpendicular direction relative tothe longitudinal axis, the base comprising a sensor assembly having asensor, the sensor configured to sense an environmental characteristicat an access site and generate a signal representative of theenvironmental characteristic; and an electrical lead wire configured tooperatively couple the sensor to an external device, wherein theelectrical lead wire terminates at a contact point molded into or formedon a surface of the base distal to the flange and proximal to thecannula, wherein the contact point is configured to transmit the signalreceived from the sensor to the external device.
 2. The catheterassembly of claim 1, wherein the electrical lead wire forms acylindrical ring positioned about an outer surface of a cylindrical wallof the connector and proximal to the cannula.
 3. The catheter assemblyof claim 1, wherein the environmental characteristic comprises atemperature within a body lumen, a blood pressure within the body lumen,a blood glucose level, a sodium level, a potassium level, an indicationof pregnancy, a drug concentration level, a white blood cell count,different markers, proteins, or chemicals in the patient's blood stream.4. The catheter assembly of claim 1, wherein the sensor comprises atemperature sensor, a sensor that senses a chemical within a patient'sblood, a sensor that senses a marker in the patient's blood, or a sensorthat senses a protein in the patient's blood.
 5. The catheter assemblyof claim 1, further comprising an array comprising a plurality of otherelectrical lead wires and the electrical lead wire, wherein the array isarranged in a parallel configuration and embedded within the connector,wherein the array terminates at the contact point, wherein the contactpoint is configured to facilitate transmission of signals between theconnector and the external device.
 6. The catheter assembly of claim 5,further comprising a second array comprising an additional plurality ofelectrical lead wires, wherein the second array is arranged in aparallel configuration and embedded within the connector, wherein thesecond array terminates at a second contact point molded into or formedon the surface of the base distal to the flange.
 7. A connectorconfigured to couple in fluid communication to a proximal end of acatheter, the connector comprising: a base extending along thelongitudinal axis and comprising a flange extending in a perpendiculardirection relative to the longitudinal axis, the base comprising asensor assembly having a sensor, the sensor configured to sense anenvironmental characteristic at an access site and generate a signalrepresentative of the environmental characteristic; and an electricallead wire configured to operatively couple the sensor to an externaldevice, wherein the electrical lead wire terminates at a contact pointmolded into or formed on a surface of the base distal to the flange,wherein the contact point is configured to transmit the signal receivedfrom the sensor to the external device.
 8. The catheter assembly ofclaim 7, wherein the electrical lead wire forms a cylindrical ringpositioned about an outer surface of a cylindrical wall of theconnector.
 9. The catheter assembly of claim 7, wherein theenvironmental characteristic comprises a temperature within a bodylumen, a blood pressure within the body lumen, a blood glucose level, asodium level, a potassium level, an indication of pregnancy, a drugconcentration level, a white blood cell count, different markers,proteins, or chemicals in the patient's blood stream.
 10. The catheterassembly of claim 7, wherein the sensor comprises a temperature sensor,a sensor that senses a chemical within a patient's blood, a sensor thatsenses a marker in the patient's blood, or a sensor that senses aprotein in the patient's blood.
 11. The catheter assembly of claim 7,further comprising an array comprising a plurality of other electricallead wires and the electrical lead wire, wherein the array is arrangedin a parallel configuration and embedded within the connector, whereinthe array terminates at the contact point, wherein the contact point isconfigured to facilitate transmission of signals between the connectorand the external device.
 12. The catheter assembly of claim 11, furthercomprising a second array comprising an additional plurality ofelectrical lead wires, wherein the second array is arranged in aparallel configuration and embedded within the connector, wherein thesecond array terminates at a second contact point molded into or formedon the surface of the base distal to the flange.